The Crystal and Molecular Structure of Acetylacetonato (cycloocta-2, 4

R. CHURCHILL. Received March 14, 1966. Acetylacetonato(cycloocta-2,4-dienyl)palladium, CaHuPd(CH3COCHCOCH3), crystallizes in the triclinic space ...
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1608 MELVYN R.CHURCHILL

Inorganic Chemistry CONTRIBUTION FROM T H E CHEMISTRY DEPARTMENT, HARVARD UNIVERSITY, CAMBRIDGE, MASSACHUSETTS 02138

The Crystal and Molecular Structure of Acetylacetonato(cycloocta-2,4-dienyl)palladium BY MELVT'K R . CHURCHILL

Received March 14, 1966 ~2cetylacetonato(c~~cloocta-2,4-dienyl)pallad~um, CaH11Pd(CHBCOCHCOCH~), crystallizes in the triclinic space group P i with a = 7.07 3~ 0.02 A, b = 9.92 f 0.02 A, c = 9.89 f 0.02 A, cy = 94.8 i 0.2', p = 86.8 i 0.2", y = 109.8 += 0 . 2 O , Z = 2. A three-dimensional single-crystal X-ray structural analysis, based on 1768 independent, visually-estimated reflections, has led to the location of all atoms other than hydrogen. The complex is shown to be an a-8 unsaturated allylpalladium derivative, only three atoms of the conjugated dienyl system being bonded to the metal. The three atoms constituting the r-allyl group are a t an average distance of 2.11 A from the palladium whereas the remaining two atoms of the conjugated system are 2.91 and 3.93 X distant from the metal.

Introduction Although palladium forms some of its most stable organometallic complexes with such chelating olefins as dicyclopentadiene and cycloocta-l,5-diene, the reaction of palladium salts with ccnjugated diolefins has been shown to result in the formation of a-allylpalladium species in preference to the expected 1,3-diene complexes.2,3 Thus, the reaction of cycloocta-1,3diene with sodium chloropalladite in methanol gives rise to the a-(methoxy)allyl complex (I). When this is heated, in situ, methanol is eliminated and a cyclooctadienyl complex is f ~ r m e d . Of ~ the structures (I1 and 111) proposed for this product, the former was considered t o be the more likely, since the infrared spectrum showed no absorption appropriate to an uncomplexed double bond, save for a very n-eak band a t about l6G0 cm-'. The bonding to the palladium of all five carbon atoms of a dienyl ligand as in I1 would result in an 18-electron complex. However, unlike the majority of organo transition metal complexes, square-planar complexes of a d8 Pd(I1) ion have a preference for If3 electrons in their outermost bonding and nonbonding orbitals4 This requirement is met by the alternative structure (111).

(3-pdcli' OCH,

(IfPdCY2

I

I1

(3PdCY2

I11

An X-ray structural analysis of the monomeric acetylacetonato analog was therefore undertaken in order to ascertain whether the complex had a true palladium-dienyl linkage (as in 11) or was, in fact, an a-p unsaturated 7r-allyl complex (111). A preliminary account of this work has been published.6

(1) J. Chatt, L. M. Vallarixio, and L. M. Venanzi, J . Chem. Soc., 3413 (1957). (2) S. D. Robinson and B. L. Shaw, i b i d . , 1806 (1963). ( 3 ) S. D. Robinson and B. L. Shaw, ibid., 5002 (1964). (4) L. E. Orgel, "An Introduction to Transition-Metal Chemistry: Ligand Field Theory," Methuen and C o . , London, p 149. (5) R1. R. Churchill, C h e m Coiamz~m.,625 (1963).

Experimental Section The compound was recrystallized from 40-60" petroleum ether a t - 5 ' . A single crystal of dimensions 0.3 X 0.3 X 0.15 mm was used in col1,ecting two zones of Weissenberg data (Okl and l k l ) and seven zones of precession data (hKZ, K = 0-3; hKL, L = 0-2). Precession data were collected on Ilford Industrial G X-ray film, and Weissenberg data on tripacks consisting of G, B, and C film, M o Ka radiation (% 0.7107 A ) being used throughout the analysis. No correction was applied for absorption ( M = 13.9 cn-l). X total of 1753 independent reflections were estimated visually using a calibrated wedge made from the crystal under investigation. The observed intensities m-ere corrected for Lorentz and polarization effects and placed on a single scale by comparison of common reflections. Unobserved reflections were ignored. All data were initially placed on the absolute scale suggested by a Wilson plot, which also indicated the over-all temperature factor, B = 3.44 A 2 . During the refinement of positional and thermal paramcters (vide inj'm), the scale of each of the nine zones was also allowed to refine, but the maximum deviation from the original scale was only about 4y0a t the conclusion of the analysis.

Unit Cell and Space Group The compound appcared to crystallize in a triclinic form. Since a systematic survey of the reciprocal lattice failed to produce evidence for any symmetry other than that imposed by the Friedel condition, the crystal; were assumed to be truly triclinic. The space group is therefore PI (no. 1) or P i (no. 2). The latter was chosen since, statistically, it occurs with considerably greater frequency than PI when 2 = 2. The accurate solution of the structure confirmed this assignment Unit-cell dimensions wcre obtained from zero-layer 1.5118 A). photographs taken with Cu Kar radiation The 0kZ Weissenberg film was calibrated using aluniinum powder ( a ~ = l 4.049 A) ; the hk0 and h0Z precession photographs were calibrated with a single crystal of sodium chloride (ayac1 = 5.640 A). The cell constants thus obtained are: a = 7.07 0.02 A, 0 = 9.92 f 0.02 A, c = 9.89 f 0.02 A, CY = 94.8 0.2', p = 86.6 i 0.2", y = 109 8 f 0.2". The unit-cell volume is 649.5 A3; the observed density is 1.58 f 0.05 g cmP3, in satisfactory agreement with the calculated density (for 2 = 2 and Jl = 312.4) of 1.60 g cm+. The total number of electrons per unit cell is 316; on the scale of Table 111, Fo0o = 1580.

(x

*

*

Vol. 5, No. 9, September 1966

ACETYLACETONATO(CYCLOOCTA-2,4-DIENYL)PALLADIUM

TABLE I CsHllPd(CH3COCHCOCH3): FINAL POSITIONAL PARAMETERS, WITH ESTIMATED STANDARD DEVIATIONS Atom Pd 01 0 2

CI C2 Ca C4 Cs Ca

C7 CS cs ClO C11 Cl? CiZ

x

104,(x)

0.20288 0.2916 0.0121 0.2381 0.1108 0.0115 0.3220 -0.1278 0.1751 0.2496 0.4214 0.6086 0.6904 0.5785 0.4397 0.2866

0.8 8. 7. 10. 10. 11. 13. 16. 10. 12. 10. 10. 11. 12. 12. 11.

Y

104~(~)

0.16445

0.0899 0.2457

0.8 7. 8.

0.1156 0.1891 0.2452 0.0487 0,3244 0,2439 0.1278 0.1337 0.2561 0.3518 0.3792 0.4600

10. 10. 11. 14. 13. 12. 13. 8. 11. 12. 12. 11.

0.4019

10.

104~(2)

Z

0.02534 0.1930 0.1496 0.3150 0.3593 0.2801 0.4157 0.3494 -0.1617 -0,1844 -0.1181 -0.0954

-0,1940 -0.3009 -0,2545 -0,1489

0.6 6. 7. 8. 9. 10. 10. 13. 9. 9. 8. 9. 10. 10. 10. 10.

Structure Determination The three-dimensional Pattersona synthesis P(UVW) contained large peaks corresponding to the palladiumpalladium vectors f (2x, 2y, 2z), leading to the unambiguous assignment of the palladium position to X = 0.203, Y = 0.166, Z = 0.028. A three-dimensional Fourier6 map, phased only by the palladium atom, R ( = ZllFol - \Fol\/ZiFol)= 0.27, led to the location of the two oxygen atoms and five carbon atoms of the acetylacetonate group, but a number of subsequent electrondensity syntheses were required before all eight carbon

T

= exp(

- [blJz2

+

b22k2

1609

+ b d 2 + 2blzhk + 2bi3hl -k 2bsakl]]

Three cycles of refinement led to a reduction in the discrepancy index to the final value R = 7 . 0 8 ~ 0a1t which stage refinement was discontinued. Weighting factors used in the least-squares treatment were derived from the following estimated errors in intensities: ~ ( 1 = ) 0.11 if I > 2 O I m i n , a(1) = 2 I m 1 n if 1 5 20Irnin,where I m i n is the minimum observable intensity for the zone under consideration. During the analysis the scattering factors for neutral palladium, oxygen, and carbon were used ,8 contributions from the hydrogen atoms were not included in the calculation. Dispersion corrections are small and were ignored. Final atomic coordinates are shown in Table I, and anisotropic thermal parameters in Table 11. The standard deviations u ( j ) in each of these tables were estimated by the least-squares program ORFLS’ from the diagonal element (a,,) of the matrix inverse to the normal equation matrix. lo Observed and calculated structure factors are collected in Table 111. The Molecular Structure The over-all molecular stereochemistry and the numbering of atoms in the complex are illustrated in

TABLE I1 ANISOTROPIC THERMAL PARAMETERS CsHllPd(CH3COCHCOCH3): FINAL 10‘bn ( u )

l O 4 b z ~( u )

104baa( u )

lO4b12

(u)

104b1a

(u)

104b23( u )

221.3(1.3) 117.6(1.1) 101.6 (0.8) 60.8 (0.7) 21.7 (0.5) 18.3 (0.7) 25(7.) 123 ( 7 . ) 108 (10. ) 01 311 (13.) 165 (10. ) 39(9.) 66(9.) 0 2 273(11.) 151 ( 9 . ) 149 (8. ) 105(9.) 71 ( 7 . ) 3(11.) c1 227 (15. ) 97 (11.) 105 ( 9 . ) 14(12.) 7(9.) -9(12.) cz 248 (15. ) 120 (11.) 113(9.) 27(12.) 29(10.) 19(13.) c 3 233 (16.) 109 (12. ) 149 (11. ) 32(12.) 59(11.) 58(15.) C4 359 (21. ) 212 (17. ) 124 ( 11. ) 105 (16. ) -7 (11.) 149 (15. ) c 6 426 (21. ) 189 (16. ) 217 (15. ) 154 ( 17. ) -3(16.) 24 (14. ) co 214 (15. ) 100 (9. ) 202 (17. ) 31 ( 1 3 . ) -30(9.) lO(13.) CI 326 (20. ) 153 (14. ) 94(9.) 91 (17.) 30(10.) - 13 (11.) 64(10.) 27 (10. ) CS 280 (17. ) 84(9.) ll6(9.) CS 225 ( 15. ) 169 (14. ) 136 (10.) 67(12.) 30(10.) 48 (14. ) 64 (14, ) -32 (14. ) 142 (18. ) 44(19.) ClO 248 (18. ) 184 ( 17, ) 29 ( 1 4 . ) 131 (11,) 46(14.) 64(12.) Cll 323 (20.) 152 (15. ) 150 (20. ) 85(15.) 94(17.) ClZ 328 (21. ) 140 (13. ) 43(19.) 135 (11.) 77(12.) - 12 (11.) e 1 3 315 (18. ) 114 (10. ) 17 (13 . ) a B , the equivalent isotropic temperature factor, is obtained by averaging 4b1t/a*~, 4b~z/b*~, and 4b33/~*~. Pd

atoms of the cyclooctadienyl group had been unambiguously located. The first structure-factor calculation,’ phased by all atoms other than hydrogen, had a discrepancy index R = 0.17 which converged, after five cycles of least-squares refinement of positional and isotropic thermal parameters, to a value R = 0.102. T h e small standard deviations for the isotropic thermal parameters prompted continuation of the refinement using anisotropic thermal parameters ( T ) defined by (6) Patterson and Fourier syntheses were computed using ERFR-2, a twoand three-dimensional Fourier program for the I B M 709/7090 by W. G. Sly, D. P. Shoemaker, and J. H. van der Hende. (7) Structure-factor calculations and full-matrix least-squares refinement of positional and thermal parameters were performed using ORFLS, a Fortran R. Busing, K, (3. Martin, and H. A. Levy. least-squares program by

w,

B , a A2

3.97 5.03 5.28 3.81 4.31 4.89 6.17 7.49 4.88 4.90 4.12 5.04 5.52 5.35 5.48 4.92

Figure 1. Intramolecular distances and angles are listed in Table IV, along with their average estimated standard deviations (esd values) .I1 The palladium atom is within bonding distance of (8) “International Tables for X-Ray Crystallography,” Vol. 3, T h e Kynoch Press, Birmingham, England. Values for palladium are taken from p 211; those for oxygen and carbon are from p 202. (9) T h e corrected scattering factor for palladium fe = fo,@ 47 i4f”, where 4f’ = -1.0 electron and 4f” = +1.3 electrons: ref 8, p 216. (10) u ( j ) = [ul,(Bw42)/(m - n)]l’z, where m is the number of observations, n the number of variables in the refinement, and Z v 4 2 the summed, weighted, discrepancy between observed and calculated structure factors (11) Since the esd values are calculated using only the diagonal elements of the inverted normal equation matrix,’o it is probable t h a t these represent a slight underestimate of the true errors. T h e slow photodecomposition of the crystal by X-rays during the course of the analysis may also have led to some systematic errors t h a t will tend t o increase the esd values. Fortunately, a comparison of chemically equivalent bond lengths and angles (Table IV) shows only one such set (CI-C~and Ca-Cs) where t h e difference (0.062 A) is greater than 3 u (0.054 A).

+

+

lGlO

MELVYN R.CHURCHILL

only three atoms of the 2,4-dienyl system. The complex is therefore an a-P unsaturated a-allylpalladium derivative. With the acetylacetonate anion and the a-allyl anion each contributing four electrons to the metal, the molecule may formally be regarded as a square-planar complex of a d8 Pd(I1) ion, with 16 electrons in its outermost bonding and nonbonding orbitals : the value of 90.4" found for the angle 01-Pd-02 is close to the ideal value expected for a square-planar stereochemistry. The acetylacetonate ligand is bonded to the metal via its two oxygen atoms, the mean palladium-oxygen distance being 2.085 (i0.008) A ; within the limits of experimental error, the acetylacetonate group has the expected Czvsymmetry and is planar (ex-

Inorganic C h m i c l v y

eluding hydrogen atoms). The packing diagrams, Figures 2 and 3, illustrate this clearly. The complex is seen to be monomeric, there are no short intermolecular contacts involving the unsaturated carbon atoms CP and Clo, and the shortest Pd-Pd distance ( 3 558 X from Pd(x, y , z ) to Pd(--x, -y, - z ) is considerably longer than that in dimeric a-allylpalladium acetate," where the Pd-Pd distance of 2.94 X represents, a t most, a n extremely weak bonding situation The cyclooctadienyl ligand is in a puckered conformation, somewhat reminiscent of octasulfur, but rather irregular, due to the constraints imposed by the variation in the car(121 II R. Chuichill and R hlason, S a t U t e 204, 777 (1964) (13 i; C Abrahams, Aria C ? y s l , 8 , 661 (1953)

Vol. 5, No. 9, September 1966

AcETYLRcETONATO (CYCLOOCTA-2,4-DIENYL)PALLADIUM

1611

"3 d 0

\

Figure ~ . - C ~ H I I P ~ ( C H ~ C O C H C O C Hstereochemistry ~): and numbering of atoms. The molecule is projected along a.

TABLE IV DISTANCES C8HI1Pd(CHBCOCHCOCH~):INTERATOMIC AND A N G L E S ~ ~ ~ Atoms

Pd-01 Pd-Oz Pd-cs Pd-C, Pd-c8 Pd-Ci Pd-Ca Pd-Cs Pd-C4 Pd-C6 Pd-Cg Pd-Cis Pd-Cio Pd-Cii Pd-Ci2 01-c1

Orc3 c1-c2

CZ-c3 G-C,

cl-c, c3-c,

OrC2 02-cz 01-02

Distance, A

Atoms

(i) From Palladium Atom 2.0801 01-Pd-02 2.0891 Cs-Pd-C? CrPd-Cs 2.103 Cs-Pd- c 8 01-Pd-Cs 2.120) 02-Pd-Cs 2.973 01-Pd-Cs 3.335

Angle, deg

90.4

/J

P Figure 2.-CsH11Pd( CH~COCHCOCHB) : the packing of molecules in the crystal, viewed along a.

38.6 69.8 100.3

4.368 2.917 2.914 3.940 4.284 4.070 (ii) In AcetyIacetonato Ligand Pd-01-Ci 1.275 Pd-Oz-Ca 1.291 01-C1-C2 1.372 O~-C~-CZ 1.348 2.423 C1-C2-C3 01-C1-C, 1.492 1.554 Oz-C3-c6 Cz-c1-c, 2.378 2.393 c2-c3-c6 2.959

I

i

123.7 121.3 127.8 130.2 126.1 112.7 111.3 119.4 118.5

c2-c, cz-c, arc, 02-c,

2.354 (iii) In Cycloocta-2,4-dienyl Ligand

ci3-cs-c7 129.8 CVc7 1.394 CB-cI-CR 119.0 C,-Ca 1.417! 1.475 C7-Cs-Cg 129.1 Cs-cs C9-C10 1.380 C8-CS-ClO 121.1 C1o-C11 1.451 Cg-Cio-Cii 125.0 c10-c11-c1z 114.9 C l r Cl2 1.496 Cii-Ciz-Ci3 118.6 C12-C13 1.464 Ciz-Cis-Cs 116.8 C1a-C6 1.495 a Average estimated standard deviations are as follows: u(Pd-0) = 0.008 A; u(Pd-C) = 0.012 A; u(0-C) = 0.015 A; u(C-C) = 0.018 A ; these values do not include any contribution from errors in the unit-cell dimensions. Chemically equivalent distances and angles are enclosed in braces.

Figure 3.-CsH11Pd( CH3COCHCOCHa) : the packing of molccules in the crystal, viewed along c.

bon-carbon bond order around the ring and by the metal-ligand bonding. The dihedral angles between the four "quadrants" of the cyclooctadienyl ligand are :

C6-C.i-C8, C8-C9-ClO, 71.3" ; cS-c9-clO, clO-Cll-c12, 82.3" ; ClO-Cll-Cl2, ClTC13-C6, 79.6" ; c12-c13-c6, CSC7-Cs, 85.8'. The carbon atoms CSand CIOare distant 2.917 and 3.940 A from the palladium ion and are obviously not involved in the metal-ligand bonding; the Cs-Clo bond distance of 1.38 A indicates that this is the remaining part of the unsaturated system. The carbon

1612 NOTES

Inorgalzic Chemistvy

atoms of the n-allyl grouping, c6, c7, and cs,are, respectively, 2.115, 2.103, and 2.120 A distant from the palladium ion. These values are in excellent agreement with those obtained by Sniith14 in his accurate low-temperature analysis of dimeric n-allylpalladium chloride (2.123, 2.108, 2.121 A ; u = 0.008 A). It is interesting to note that, in each case, the central carbon atom is slightly closer to the metal than are the terminal carbon atoms. The differences are, however, too small to be considered statistically significant. The apical angle of 119.0' for the allyl group and a mean carbon-carbon bond length of 1.405 A for the allyl system in the present complex may be compared to Smith's values of 119.8' and 1.376 A. The coordination plane of the palladium ion, as defined by the atoms Pd, 0 1 , and 0 2 , fits the equation 1.924X 3.61GY 0.5902= 1. Atoms Cs and C8are 0.22 and 0.40 A above, and C7 is 0.30 A below, this plane. The x-allyl group (C6-c?-CS) makes a dihedral angle of 121.5' with the coordination plane of the palladium ion. This is not an isolated example of this phenomenon. Other n-allyl complexes show the same effect to varying degrees (see Table V). This rather surprising result has been explained by Kettle and

+

+

Mason,16 n-ho are able to predict a value of approximately 110°, by considering the various n-allylpalladium overlap integrals. TABLE TTHEDIHEDRAL -4NGLE

BZTTTEES T H E h l E T A L COORIDSATION

P L A S E AXD T H E T - ~ ~ L L YSLY S T E M I N A N U M B E R O F r-ALLYLPALLADIUM COMPLEXES

Complex

Dihedral angle, deg

Kef

[exo-CzHsO[ C ~ J C G H ;PdCllz )~] 95u b [endo-CnHjO[C4(C5Hj).llPdCl!a 95" 0 [ CsHjPdCl]2 111.5 13 CHsC3H4Pd[P(CijH;)s]C1 116 c [C&PdCHaCOZl2 117 (av) 11 CZHi,Pd( CHaCOCHCOCH3) 121 This angle would probably be greater but for the effect of the nonbonding interaction between the fourth carbon of the cyclobutenyl system and the palladium atom. I' L . F. Dah1 and UT.E. Oberhansli, Inorg. Chena., 4, 629 (1965). R . Mason and D . R . Russell, Chenz. Cow?nzzin.,26 (1968).

Acknowledgmente.-The author is indcbted to Dr. S. D. Robinson, who provided the sample. This research has been generously supported by grants from the William F. Milton Fund of Harvard University, the Xational Science Foundation (grant No. GP4223), and the Advanced Research Projects Agency. (15) S. F. A . Kettle and I